MARS: A Simulation Environment For Marine Robotics

被引:0
|
作者
Tosik, Thomas [1 ]
Maehle, Erik [1 ]
机构
[1] Med Univ Lubeck, Inst Comp Engn, D-23538 Lubeck, Germany
来源
2014 OCEANS - ST. JOHN'S | 2014年
关键词
D O I
暂无
中图分类号
U6 [水路运输]; P75 [海洋工程];
学科分类号
0814 ; 081505 ; 0824 ; 082401 ;
摘要
In this paper, we present a simulation environment for marine robotics called MARS. MARS is a Hardware-in-the-Loop online simulation environment for multiple AUVs and USVs. Through the usage of the 3D-Engine jMonkeyEngine, sophisticated underwater graphics are possible. Several actuators and sensors enable complete integration tests in various scenarios. A special focus is set on the sonar which uses a ray-based approach. Water currents together with waves, computation of the center of buoyancy, and volume calculation enable a realistic physical behavior under and on the water surface. Finally, direct feedback from the real marine robots at our institute assists in the evaluation of MARS.
引用
收藏
页数:7
相关论文
共 50 条
  • [1] MARS: A Simulation Environment for Marine Swarm Robotics and Environmental Monitoring
    Tosik, Thomas
    Schwinghammer, Jasper
    Feldvoss, Mandy Jane
    Jonte, John Paul
    Brech, Arne
    Maehle, Erik
    OCEANS 2016 - SHANGHAI, 2016,
  • [2] Intelligent Marine Robotics Modelling, Simulation and Applications
    Chin, Cheng Siong
    Cui, Rongxin
    JOURNAL OF MARINE SCIENCE AND ENGINEERING, 2020, 8 (06)
  • [3] SSim: NASA Mars Rover Robotics Flight Software Simulation
    Verma, Vandi
    Leger, Chris
    2019 IEEE AEROSPACE CONFERENCE, 2019,
  • [4] Simulation and analysis of the multipath environment of Mars
    Chukkala, Vishwanath
    De Leon, Phillip
    2005 IEEE Aerospace Conference, Vols 1-4, 2005, : 1678 - 1683
  • [5] SIMULATION OF THE DYNAMIC BEHAVIOR OF ROBOTICS IN AN EXTREME ENVIRONMENT
    JANOCHA, H
    PAPADIMITRIOU, I
    ROBOTICS AND COMPUTER-INTEGRATED MANUFACTURING, 1991, 8 (03) : 163 - 169
  • [6] Simulation on Thermal Radiation Environment on Surface of Mars
    Zhang L.
    Xu X.-H.
    Yuhang Xuebao/Journal of Astronautics, 2020, 41 (09): : 1221 - 1227
  • [7] High level architecture for collaborative robotics simulation environment
    Smid, GE
    Cheok, KC
    Gerhart, G
    Hudas, G
    INTELLIGENT SYSTEMS, 2002, : 161 - 166
  • [8] A realistic simulation environment as a teaching aid in educational robotics
    Lima, Jose
    Kalbermatter, Rebeca B.
    Braun, Joao
    Brito, Thadeu
    Berger, Guido
    Costa, Paulo
    2022 LATIN AMERICAN ROBOTICS SYMPOSIUM (LARS), 2022 BRAZILIAN SYMPOSIUM ON ROBOTICS (SBR), AND 2022 WORKSHOP ON ROBOTICS IN EDUCATION (WRE), 2022, : 430 - 435
  • [9] Development of a simulation scenario for cooperative robotics studies with marine crafts
    Giron-Sierra, JM
    Jimenez, JF
    Dominguez, A
    De La Cruz, JM
    Proceedings of the 7th WSEAS International Conference on Automatic Control, Modeling and Simulation, 2005, : 174 - 179
  • [10] Modeling and Simulation of Supersonic Parachute Inflation in Mars Environment
    Zhao, Miao
    Zhang, Sijun
    Zhang, Zhang
    Wang, Qi
    Liu, Yu
    Li, Jian
    MAN-MACHINE-ENVIRONMENT SYSTEM ENGINEERING, MMESE, 2022, 800 : 445 - 451
12345